Efficient computation of forward kinematics and Jacobian matrix of a Stewart platform-based manipulator

Author

Nguyen, Charles C. ; Zhou, Zhen-Lei ; Antrazi, Sami S. ; Campbell, Charles E., Jr.

Author_Institution

Dept. of Electr. Eng., Catholic Univ. of America, Washington, DC, USA

fYear

1991

fDate

7-10 Apr 1991

Firstpage

869

Abstract

The authors consider the problem of efficient computation of the forward kinematics of a six-degree-of-freedom robot manipulator built to study autonomous assembly of parts in space. The manipulator, based on the Stewart platform mechanism, consists mainly of two platforms and six linear actuators. The closed-form solution of the inverse kinematics is formulated in such a way as to optimize the computation efficiency of the iterative solution of the forward kinematics using the Newton-Raphson method. A modified Jacobian matrix which relates length velocities to Cartesian translational velocities and time rates of change of roll-pitch-yaw angles is introduced. Computer simulation is performed to evaluate the computation efficiency of the developed computation schemes

Keywords

aerospace control; assembling; digital simulation; iterative methods; kinematics; matrix algebra; robots; Cartesian translational velocities; Jacobian matrix; Newton-Raphson method; Stewart platform-based manipulator; aerospace control; autonomous assembly; closed-form solution; computation efficiency; forward kinematics; iterative solution; length velocities; linear actuators; roll-pitch-yaw angles; space assembly; Closed-form solution; Hydraulic actuators; Iterative methods; Jacobian matrices; Kinematics; Manipulators; Newton method; Optimization methods; Orbital robotics; Robotic assembly;

fLanguage

English

Publisher

ieee

Conference_Titel

Southeastcon '91., IEEE Proceedings of

Conference_Location

Williamsburg, VA

Print_ISBN

0-7803-0033-5

Type

conf

DOI

10.1109/SECON.1991.147884

Filename

147884